EP2326889A2 - Systeme et procede de capture d'energie solaire et procede de fabrication associe - Google Patents
Systeme et procede de capture d'energie solaire et procede de fabrication associeInfo
- Publication number
- EP2326889A2 EP2326889A2 EP09815304A EP09815304A EP2326889A2 EP 2326889 A2 EP2326889 A2 EP 2326889A2 EP 09815304 A EP09815304 A EP 09815304A EP 09815304 A EP09815304 A EP 09815304A EP 2326889 A2 EP2326889 A2 EP 2326889A2
- Authority
- EP
- European Patent Office
- Prior art keywords
- light
- waveguide
- waveguide component
- prism
- lens array
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Withdrawn
Links
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Classifications
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B19/00—Condensers, e.g. light collectors or similar non-imaging optics
- G02B19/0033—Condensers, e.g. light collectors or similar non-imaging optics characterised by the use
- G02B19/0038—Condensers, e.g. light collectors or similar non-imaging optics characterised by the use for use with ambient light
- G02B19/0042—Condensers, e.g. light collectors or similar non-imaging optics characterised by the use for use with ambient light for use with direct solar radiation
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S23/00—Arrangements for concentrating solar-rays for solar heat collectors
- F24S23/12—Light guides
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B29—WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
- B29D—PRODUCING PARTICULAR ARTICLES FROM PLASTICS OR FROM SUBSTANCES IN A PLASTIC STATE
- B29D11/00—Producing optical elements, e.g. lenses or prisms
- B29D11/00009—Production of simple or compound lenses
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B29—WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
- B29D—PRODUCING PARTICULAR ARTICLES FROM PLASTICS OR FROM SUBSTANCES IN A PLASTIC STATE
- B29D11/00—Producing optical elements, e.g. lenses or prisms
- B29D11/00865—Applying coatings; tinting; colouring
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S23/00—Arrangements for concentrating solar-rays for solar heat collectors
- F24S23/30—Arrangements for concentrating solar-rays for solar heat collectors with lenses
- F24S23/31—Arrangements for concentrating solar-rays for solar heat collectors with lenses having discontinuous faces, e.g. Fresnel lenses
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S3/00—Direction-finders for determining the direction from which infrasonic, sonic, ultrasonic, or electromagnetic waves, or particle emission, not having a directional significance, are being received
- G01S3/78—Direction-finders for determining the direction from which infrasonic, sonic, ultrasonic, or electromagnetic waves, or particle emission, not having a directional significance, are being received using electromagnetic waves other than radio waves
- G01S3/782—Systems for determining direction or deviation from predetermined direction
- G01S3/785—Systems for determining direction or deviation from predetermined direction using adjustment of orientation of directivity characteristics of a detector or detector system to give a desired condition of signal derived from that detector or detector system
- G01S3/786—Systems for determining direction or deviation from predetermined direction using adjustment of orientation of directivity characteristics of a detector or detector system to give a desired condition of signal derived from that detector or detector system the desired condition being maintained automatically
- G01S3/7861—Solar tracking systems
-
- G—PHYSICS
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- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B19/00—Condensers, e.g. light collectors or similar non-imaging optics
- G02B19/0004—Condensers, e.g. light collectors or similar non-imaging optics characterised by the optical means employed
- G02B19/0028—Condensers, e.g. light collectors or similar non-imaging optics characterised by the optical means employed refractive and reflective surfaces, e.g. non-imaging catadioptric systems
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B3/00—Simple or compound lenses
- G02B3/0006—Arrays
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
- G02B6/0001—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings specially adapted for lighting devices or systems
- G02B6/0011—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings specially adapted for lighting devices or systems the light guides being planar or of plate-like form
- G02B6/0033—Means for improving the coupling-out of light from the light guide
- G02B6/0035—Means for improving the coupling-out of light from the light guide provided on the surface of the light guide or in the bulk of it
- G02B6/0038—Linear indentations or grooves, e.g. arc-shaped grooves or meandering grooves, extending over the full length or width of the light guide
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
- G02B6/0001—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings specially adapted for lighting devices or systems
- G02B6/0011—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings specially adapted for lighting devices or systems the light guides being planar or of plate-like form
- G02B6/0033—Means for improving the coupling-out of light from the light guide
- G02B6/005—Means for improving the coupling-out of light from the light guide provided by one optical element, or plurality thereof, placed on the light output side of the light guide
- G02B6/0053—Prismatic sheet or layer; Brightness enhancement element, sheet or layer
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- G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
- G02B6/0001—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings specially adapted for lighting devices or systems
- G02B6/0011—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings specially adapted for lighting devices or systems the light guides being planar or of plate-like form
- G02B6/0075—Arrangements of multiple light guides
- G02B6/0078—Side-by-side arrangements, e.g. for large area displays
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- G—PHYSICS
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- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B6/00—Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
- G02B6/24—Coupling light guides
- G02B6/26—Optical coupling means
-
- G—PHYSICS
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- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B7/00—Mountings, adjusting means, or light-tight connections, for optical elements
- G02B7/003—Alignment of optical elements
- G02B7/005—Motorised alignment
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L31/00—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof
- H01L31/04—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof adapted as photovoltaic [PV] conversion devices
- H01L31/054—Optical elements directly associated or integrated with the PV cell, e.g. light-reflecting means or light-concentrating means
- H01L31/0543—Optical elements directly associated or integrated with the PV cell, e.g. light-reflecting means or light-concentrating means comprising light concentrating means of the refractive type, e.g. lenses
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L31/00—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof
- H01L31/04—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof adapted as photovoltaic [PV] conversion devices
- H01L31/054—Optical elements directly associated or integrated with the PV cell, e.g. light-reflecting means or light-concentrating means
- H01L31/0547—Optical elements directly associated or integrated with the PV cell, e.g. light-reflecting means or light-concentrating means comprising light concentrating means of the reflecting type, e.g. parabolic mirrors, concentrators using total internal reflection
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L31/00—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof
- H01L31/04—Semiconductor devices sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof adapted as photovoltaic [PV] conversion devices
- H01L31/054—Optical elements directly associated or integrated with the PV cell, e.g. light-reflecting means or light-concentrating means
- H01L31/055—Optical elements directly associated or integrated with the PV cell, e.g. light-reflecting means or light-concentrating means where light is absorbed and re-emitted at a different wavelength by the optical element directly associated or integrated with the PV cell, e.g. by using luminescent material, fluorescent concentrators or up-conversion arrangements
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B3/00—Simple or compound lenses
- G02B3/0006—Arrays
- G02B3/0037—Arrays characterized by the distribution or form of lenses
- G02B3/0056—Arrays characterized by the distribution or form of lenses arranged along two different directions in a plane, e.g. honeycomb arrangement of lenses
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B10/00—Integration of renewable energy sources in buildings
- Y02B10/10—Photovoltaic [PV]
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B10/00—Integration of renewable energy sources in buildings
- Y02B10/20—Solar thermal
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/40—Solar thermal energy, e.g. solar towers
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/40—Solar thermal energy, e.g. solar towers
- Y02E10/47—Mountings or tracking
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/50—Photovoltaic [PV] energy
- Y02E10/52—PV systems with concentrators
Definitions
- the present invention relates to solar energy systems, and methods and, more particularly, to systems and methods for capturing .solar energy that operate at least in part by way of concentrating received light prior to conversion of the light into electrical or other power, as well as to methods of manufacturing such systems.
- PV photovoltaic
- a solar energy system employing such a solar concentration device in combination with PV cellos) covering a relatively small surface area can potentially produce, at a lower cost, the same high level of energy output as that achieved by a solar energy system employing only PV cell(s) of the same or greater area.
- a solar energy system employing such a solar concentration device in addition to high efficiency PV cell(sj covering a relatively small area can achieve higher levels of energy output than would be possible using those PV cellos) alone, even if those cells covered a large area.
- existing solar energy systems employing both PV cellfs) and solar concentration devices have certain disadvantages as well, In particular, some stationary solar concentration devices tend to be not very efficient.
- one particular type of existing solar energy system employing both PV cell(s) and solar concentration devices is a system employing one or more fluorescent solar concentrators fFSCs ⁇ . In such a device, light incident on the surface of a slab waveguide is absorbed by an atomic or molecular transition of matciial embedded in the slab Upon absorption, some of the energy is then emitted as fluorescence uniformly in all directions, and this fluorescent light is emitted at a longer wavelength with less energy than the incident light.
- ⁇ n additional problem associated with some conventional solar concentrators is that, for proper operation, such solar concentrators require sunlight that is incident from a particular direction relative to the concentrator l hat is, while such solar concentrators are able to condense/magnify light incident over a large area onto a smaller area PV cell, such large magnifications require precise alignment that must be maintained as the sun moves through the sky thiough the daily arc, and through the seasonal variation of elevation.
- the inventors have further recognized that a new form of solar energy system employing slab waveguides can be achieved having higher efficiency than existing systems if, instead of employing FSCs, the solar concentrators instead are built by placing a lens array adjacent to a slab waveguide formed between a low index cladding layer and an additional layer having prism facets, with the lens array being along the cladding layer opposite the additional layer of the slab waveguide having the prism facets.
- the prism facets total internal reflection can be achieved within the slab waveguide with respect to much if not all incoming light directed into the slab waveguide, and this light can in turn be directed to one or more PV cells positioned at one more ends/edges of the slab waveguide.
- the present inventors have also recognized the desirability of solar energy systems that are capable of receiving light from changing angles of incidence. Consequently, while prism facets with constant optical properties can be employed in at least some embodiments of the present invention, the present inventors have further recognized that in at least some other embodiments of the present invention the prism facets can be formed or revealed by way of one or more materials and/or processes that allow for the prism facet characteristics to vary, including location relative to the microlens. depending upon the light incident upon those prism facets. Also, in at least some other embodiments, components of the solar energy systems can be shifted slightly in various manners to also allow light of various angles of incidence to be received and directed to PV cells.
- the waveguide with the prism facets can be shifted relative to one or more lens devices.
- the present inventors have also recognized the desirability of increasing the degree to which light is concentrated onto less numbers of (or smaller) PV cells, as well as ihe desirability of being able to receive multiple light components rather than merely a single light component or single range of light components, and have further developed various arrangements that facilitate achieving such objectives.
- the present invention relates to a system for capturing solar energy.
- the system includes a first lens array having a plurality of lenses, and a first waveguide component adjacent to the lens array, where the waveguide component receives light, and where the waveguide component includes an array of prism or mirrored facets (or other light-directing feature) arranged along at least one surface of the waveguide component.
- the system further includes at least one photovoltaic cell positioned so as to receive at least a portion of the light that is directed out of the waveguide. At least some of the light passing into the waveguide component is restricted from leaving the waveguide component upon being reflected by at least one of the prism or mirrored facets, whereby the at least some light restricted from leaving ihe waveguide component is directed by the waveguide toward the at least one photovoltaic cell.
- the present invention relates to a method of manufacturing a solar energy collection system.
- the method includes providing a waveguide layer, providing a lens array in combination with the waveguide layer, and forming prism or mirrored facets on the waveguide layer by exposing the waveguide layer and at least one additional layer to light.
- the present invention relates to a method of capturing solar energy.
- the method includes receiving light at a waveguide component, and reflecting at least a portion of the received light at a plurality of prism or mirrored facets formed along a surface of the waveguide component, where substantially all of the reflected light experiences total internal reflection within the waveguide component subsequent to being reflected by the prism or mirrored facets.
- the method also includes communicating the reflected light within the waveguide component toward an edge surface of the waveguide layer, and receiving the communicated reflected light at a photovoltaic ceil upon the communicated reflected light being transmitted through the edge surface.
- the present invention relates to a system for capturing solar energy.
- the system includes an optical waveguide layer, having an upper and lower cladding layer, and a lens array having a plurality of lenses, disposed above the upper cladding layer, and upon which sunlight is incident.
- the system also includes an array of injection features formed on the optical waveguide layer and arranged so that each injection feature is located at or near the focus of a respective one of the lenses, wherein each of the injection features is oriented so that light focused from the lens onto the respective injection feature is coupled into the optical waveguide layer.
- the system further includes at least one photovoltaic cell positioned along at least one edge surface of the optical waveguide, wherein the light coupled into the optical waveguide layer is guided by the waveguide toward and absorbed by the at least one photovoltaic cell.
- the present invention relates to a solar photovoltaic system that includes a solar concentrator that collects direct sunlight into a small-area PV cell, overlapping in light collection area with a non-concentrated solar panel that collects indirect sunlight into a large-area PV or solar-thermal panel.
- FlG. 1 is a schematic, perspective, exploded view of an additional exemplary solar energy device employing components allowing for concentration and collection of incoming light, in accordance with at least one embodiment of the present invention
- FlG. 2 is a schematic, cross-sectional elevation view of the solar energy device of
- FIG, 3 is a schematic diagram illustrating exemplary steps of a manufacturing process that can be employed to produce a device such as that shown in FiGS. 1-2;
- FIGS, 4A-4C are flow diagrams further illustrating other exemplary manufacturing processes that can be employed in producing a device such as that shown in FiGS. 1 -2;
- FIG. 5 is an additional schematic, cross-sectional elevation view of the solar energy device of FIG. 1 illustrating possible exemplary operation when incident light impinging ihc solar energy device is tilted relative to an axis normal to the solar energy device;
- FIG, 6 is a schematic, cross-sectional elevation view of a further exemplary solar energy device differing from that of FIGS.
- FIG. 7 is a flow chart illustrating exemplary steps of operation of the solar energy device of FlG. 6, particularly in terms of its reaction to positional variation of sunlight;
- FIGS. 8-14 are additional schematic, cross-sectional elevation views of additional exemplary embodiments of solar energy devices that employ various forms of micro- tracking;
- FIGS. 15-17 are additional schematic, cross-sectional elevation views of further exemplary embodiments of solar energy devices that allow for differ manners of extraction of light from waveguides of the solar energy devices:
- FlG. 18 is an additional schematic, perspective view of a solar energy system in the form of a planar concentrator array
- FiGS, 19-23 are additional schematic, cross-sectional elevation views of further exemplary embodiments of solar energy devices that allow tor various spectral components of light to be directed to different PV cells;
- FIGS. 24A-24D, 26A-C and 28B are further schematic perspective views of portions of additional exemplary embodiments of solar energy devices that are arranged to facilitate various manners of concentration of light;
- FIGS. 25, 27 and 28A are additional schematic views illustrating manners of concentration employed by some of the solar energy devices shown in FIGS. 24A-24D, 26A- C and 28B as well as at least one other type of solar energy device.
- the solar energy system 2 includes a solar concentration section 4 and multiple PV cells 6,
- the solar concentration section 4 can also be referred to as a micro-optic concentration section in view of the small size of the structure and its components relative to the overall physical structure of the system 2. More particularly as shown, the solar concentration section 4 includes a Sens array 8 having multiple lenses 10 arranged substantially along a plane.
- the solar concentration section 4 further includes additional waveguide portions 19 (aside from the lens array 8).
- the additional waveguide portions 19 include a low index cladding layer 16 and a slab waveguide 18. When the solar energy system 2 is assembled, the low index cladding layer 16 is positioned in between the lens array 8 and the slab waveguide 18.
- the low index cladding layer 16 can be, for example, a Teflon AF or related fluoropolymer material, while the slab waveguide 18 can be made from glass (e.g.. F2 flint glass) or an acrylic polymer.
- the slab waveguide 38 has a thickness 20, an inner surface 22 that is in contact with the low index cladding layer 16 (when the section 4 is assembled) and an outer surface 24 opposite the inner surface and separated from the inner surface by the thickness 20. ⁇ plurality of prism facets 26 are formed along the outer surface 24.
- the respective prism facets 26 are aligned with the respective lenses 10 and the thickness 20 is determined so that a respective focal point of each of the lenses occurs at a respective one of the prism facets, As discussed below, in practice, the prism facets 26 are much smaller in extent relative to the lenses (for descriptive purposes, the prism facets are not drawn to scale in FlG. 1 ).
- the prism facets 26 are intended to be representative of a variety of different types of injection facets or injection features that are configured to refract, reflect, diffract, scatter, and/or otherwise direct light incident thereon so that the light entirely or substantially remains within the slab waveguide 18 or at least is partly restricted from exiting the waveguide, any and all of which are encompassed by the present invention.
- the prism facets 26 particularly can be considered as injection features that are largely or entirely- refractive in their operation, other forms of injection features also encompassed by the present invention such as mirrored facets can be considered largely or entirely reflective,
- the injection features employed will provide any one or more of refraction, reflection, diffraction (e.g., in the form of a diffraction grating) or scattering.
- the prism facets 26 (or other light directing/injection features) can be formed using any of a variety of techniques that can involve, for example, embossing, molding, ruling, lithography, or photolithograpy.
- the outer surface 24 of the waveguide 18 includes an additional cladding layer in addition to the prism facets 26.
- the overall optical collection efficiency of the concentrator/solar energy system depends upon, among other things, the exact lateral and vertical position of the injection features (e.g., the positions of the injection features relative to lenses), as well as on the physical profile of the injection features (the shapes and orientations of one or more particular facet surfaces of the injection features), Among other things, the angl ⁇ (s) of the injection features (e.g., the angles of surfaces of the injection features relative to the outer surface 24 of the waveguide 18 on which those injection features arc mounted) can be of significance, Often these angles are determined in a manner that takes into account the angle(s) at which light is expected to impinge the injection features, For example, where light is expected to impact one of the prism facets 26 at smaller angles (e.g., 0 to 15 degrees relative to an axis normal to the outer surface 24 of the waveguide 18), the angle of the face
- the inner and outer surfaces 22, 24 of the blab waveguide 18 are each rectangular, such that the slab waveguide 18 has first, second, third and fourth edge t « ui faces 28, 30, 32 and 34, respectively, extending between the inner and outer surfaces, where the first and second edge surfaces oppose one another and the third and fourth edge surfaces oppose one another. While fully-reflecting coatings can optionally be applied to the third and fourth edge surfaces 32, 34, the PV cells 6 are arranged along the first and second edge surfaces 28 and M).
- each of the PV ceils 6 more particularly in the present embodiment has a width equaling the thickness 20, and extends along the entire respective one of the oppositely -oriented edge surfaces 28.
- the first and second edge surfaces 28, " U) at which the PV cells 6 are located can also be referred to as longitudinal edge surfaces since they are at opposite ends of the length of the slab waveguide 18 and are the edges toward which light is being directed by the waveguide.
- a cross-sectional view of the solas concentration section 4 of the solar energy device 2 (that is, the solar energy device 2 with the PV ceUs o icmoved) in assembled (rather than exploded form) is provided, which particularly illustrates exemplary operation of the solar concentration section 4 m channeling light to the first and second edge surfaces 28, 30 along which the PV cells b are to be mounted
- light lays e g., sunlight
- the focused light proceeds through the low mdcx cladding layer Ib and subsequently into the slab waveguide 18, with the light then proceeding from the inner surface 22 of the slab waveguide to the outer surface 24 of the slab waveguide ultimately, the focused light reaches an exemplary one of the prism facets 26 located along the outer surface 24 of the slab waveguide, with the focal point of the focused light occurring at that prism facet.
- the prisrn facets 26 in particular are reflective facets that are configured to reflect (or "inject'') the focused light back into the slab waveguide 18 at sharp angles such that when the light r ⁇ ncounters the low index cladding layer 16 it is again reflected into the slab waveguide. That is, once the prism facets 26 have acted upon the focused light, the light reflected off of the prism facets experiences total internal reflection (TlR) or at least substantially experiences TlR within the slab waveguide 18 as far as the light's interaction with the low index cladding layer 16, the outer surface 24 and the third and fourth edge surfaces 32, 34 (due to the reflective coating applied thereto) is concerned.
- TlR total internal reflection
- the TIR experienced by light within the slab waveguide 18 is completely independent of wavelength and polarization over a wide range of angles that are steeper than the critical angle.
- the angle of incidence at the first and second edge surfaces- 28, 30 is less than the critical angle, so the light can be emitted through those surfaces.
- the PV ceils typically have an anti-reflection coating (or an index-matching layer between the waveguide and the surface of the PV cell). It should be noted that the operation of the slab waveguide 18 is not perfectly efficient, since the prisrn facets 26 that reflect the light so that TlR occurs can also act to strip the light from the waveguide.
- the diameter of the local spots occurring at the prism facets 26 Is roughly one percent of the diameters of the lenses 10 (e.g., a 1 mm diameter lens can produce approximately a 10 micron spot), such that the total area of the focal sp ⁇ t is 0.01% of the area of the lens, and such that the surface of the waveguide is 99 ⁇ ) t)0 / 0 reflective (thus light can propagate for hundreds of lens diameters before significant amounts of light are lost),
- the shape and sizes of the prism facets 2ft or other injection features such as mirrored facets employed in any given embodiment can vary depending upon the embodiment (indeed, different ones of the prism facets along the same waveguide can have different shapes/sizes). Often, the particular injection features employed will desirably be tailored specifically for the application.
- the prism (or mirrored) facets 26 are symmetric, triangular in cross section, and couple light equally to the left and the right as illustrated in FlO. 2.
- the prism (or mirrored) facets 26 can have sawtooth-shaped features that reflect light primarily or entirely toward one or the other of the PV cells 6 at the opposite edge surfaces 28, 30.
- more than two PV cells are employed along more than two of the edge surfaces, or only one PV cell is employed along only one of the edge surfaces.
- there is only a single PV cell along any given one of the edge surfaces in other embodiments there are more than one PV cell along one or more of the edge surfaces.
- a "'self- alignment" process is employed to form the prism facets 26.
- the manufacturing process 40 it is particularly possible to manufacture solar energy systems 2 (especially the solar concentration sections of those systems) m sheets in d batch manner using rollers and other conventional mass-production technologies, that i ⁇ , in a roll-processing manufacturing process
- the process 40 begins at a step 41 by applying A superstrata 42, composed of acrylic or similar material, upon an assembly 44 including a slab waveguide portion upon which a low index cladding layer has already been applied (such that the cladding layer is ultimately positioned between the superstrate and the slab waveguide portion). This can be performed by way of rollers 46 as shown.
- lens array embossing is performed by way of an embossment roller 52 so as to form lenses 49 in the acrylic superstrate 42.
- an ultraviolet-curable cpoxy serving as a molding film/photoresist 54 is further applied by a molding film application roller 56 along the outer surface of the assembly 44 ⁇ that is, the surface which docs not face the acrylic superstrate 42).
- the molding film/photoresist 54 can be considered to be part ol the slab waveguide portion of the assembly 44
- a ruled p ⁇ sm master roller o0 is employed to emboss/stamp intermediate prism facet formations 62 within the molding film/photoresist 54.
- localized prism facets 66 are particularly formed in the intermediate prism facet formations 62.
- l he localized p ⁇ sm facets 66 are formed m particular by shining light from a light source (or multiple light sources) t»8 through the lenses 49, where the light ⁇ particular serves to expose apertures m the molding film/photoresist 54, That is, the light causes certain portions of the molding film/photoresist 54 that are desired as the localized prism facets 66 to be cured.
- the light source b8 can be a deep blue 420 nm light, for example, since this is the longest wavelength that will crosslink the epoxy and minimize the effect of chromatic aberrations from the lensc ⁇ .
- a solvent bath 72 removes excess uncured iacet material (e.g , removes unused, uncured material of the molding film/photoresisi 54) such that only the localized prism facets remained (approximately 99.99 of the molding film/photoresist 54 is removed).
- step 70 additional steps (not shown) involve spraying the bottom surface of the waveguide (that is, the outer surface of the assembly 44 including the localized prism facets 66 with another thin layer of low-index cladding material depositing a metal mirror on certain edge surfac ⁇ (s ⁇ of the waveguide (e.g., lhe edge surface corresponding to the surfaces 32, 34 mentioned above), and then mounting the PV cells upon the overall assembly, particularly along the remaining (uiimirrored) edge surfaec(s) of the slab waveguide (e.g.. the edge surfaces corresponding to the surfaces 28, 30 mentioned above).
- edge surfac ⁇ (s ⁇ of the waveguide e.g., lhe edge surface corresponding to the surfaces 32, 34 mentioned above
- the concentration power of the lenses 10 can vary depending upon the embodiment and, in one exemplary embodiment, the concentration power of the lenses is 5C 1 O suns.
- the length of the slab waveguide ! 8 (that is, the distance along which light is intended to flow through the waveguide, e.g., the distance between the two PV cells 6 at the edges 28, 30) can be of any arbitrary length, for example, several meters long.
- the width of the slab waveguide 18 (that is, the distance across the slab waveguide perpendicular to the distance along which light is intended to flow, and perpendicular to the thickness 20) can be arbitrarily large or small, for example, 500 millimeters or alternatively 1 meter,
- the thickness 20 can be arbitrarily large or small.
- the lenses 10 are F/2,9 lenses and the thickness is only 6 mm (which is far less than for thin parabolic reflector optics).
- a modified version of the process 40 shown as a process 80, includes a slightly-different set of operational steps than those shown in FKi. 3, More particularly as shown, the process 80 begins at a step 82 with the addition of low index cladding to one (e.g..
- a step 84 with the addition of a photosensitive polymer molding agent to an additional opposed ( ⁇ g , the bottom) surface of the slab waveguide, and further continues at a step So with the formation of prism facets in the molding agent usmg a ruled master
- a reflective coating is placed onto the prism facets
- a lens array is attached to the Sow index cladding (e g., attached to the top surface of the slab waveguide as modified to include the claddingj
- the molding agent is exposed Xo light via the lens array f inally
- mold development occurs, lollowed by remaining actions (e.g., attachment of the PV eellsj that result m a final device at a step %
- FFG 4B shows an additionally modified version of the process 80, shown as a process 100
- the process 1 (K) includes steps 10.7-108 that respectively correspond to the steps 82-% of the process 80 respectively (except insofar as no step corresponding to the step 88 is included).
- a step 101 shown to precede the step 102 merely is indicative of the fact that a slab waveguide is provided prior to the application of the low index cladding layer in the step 102, and a step 98 is shown to be performed between the steps 10b and 107. in which a reflective coating is applied to the slab waveguide (e.g., along edge surfaces such as the edge surfaces 32, ⁇ 4 of FIG 1) (The step 98 can be considered a substitute for the step 88 of FIG 4A),
- S 1 IG. 4C shows m yet another form a process 110 lor manufacturing a solar energy system such as the system 2 of FIGS 1 -2.
- the process 1 10 begins at a step 1 1 1 by applying an un-crosslmkcd photopolymcr coating onto a waveguide.
- a moid is applied to the photopolymer coating and additionally a pull vacuum is applied
- the waveguide is baked with weight (pressure) applied, partituiaiiy pressure upon the mold tending to compress the assembly as shown further, at a step 1 13. the mold is removed.
- a lens array is attached to the waveguide along its side that is opposite the side on which the photopolymer coaling is attached.
- ⁇ s illustrated particularly in FIG, 4C 5 ultraviolet light is further directed so as to he incident upon the lens array.
- the ultraviolet light in turn passes through the lens array and the waveguide and then reaches the molded photopolymer coating. Due to the focusing of the lenses of the lens array, the ultraviolet in particular only readies (is focused upon) specific portions of the molded photopolymer coating, and these specific portions of the coating in turn become crosslink ⁇ d photopolymer..
- a reflective coating is deposited upon the exposed outer surface (that is, the surface not in contact with the waveguide) of the molded photopolymer coating, including the un-crosslimed and crosslinkcd portions.
- the overall assembly is heated above a glass transition temperature (Tg), the un-cro ⁇ slinked portions of the photopolymer coating arc removed (so as to complete formation of prism facets) and a completed solar concentration section, suitable for implementation in a solar energy system such as the system 2, results.
- Tg glass transition temperature
- the solar concentrators within the above-described solar energy systems including the solar concentrator section 4 of the solar energy system 2 can be referred to as passive solar concentrators.
- the refractive/reflective properties of the lenses and prism facets K) are fixed such that variation in the angle of incidence of incoming sunlight (or other light) as a function of movement of the sun (or otherwise) alters the degree of concentration and efficiency of the device.
- F(G. 5 in this regard for example, a cross-sectional view of the solar energy system 2 of FlG. 1 is provided with respect to which incident light 157 is shown to be tilted relative to a normal axis 159 (which is perpendicular to the surfaces 22, 24 of the slab waveguide 18).
- the solar energy is modified, takes other forms, or can be operated in particular manners than as discussed above.
- the system in at least some embodiments, is mounted upon (or otherwise implemented in conjunction with) an active alignment system.
- the prism facets 2(S) are configured to be more tolerant of variations in the incidence angles of light impinging the solar energy system.
- the upward- facing lenses ] 0 can themselves be used during the construction of the system 2 to identify and form the location of the coupling prism facets 26, for example, as shown in the step 68 of RG. 3.
- the prism facets 26 that are formed in the manner described with respect to FIG, 3 are localized discrete facets intended to receive incoming light along a particular path
- the angle and intensity properties of the light used during the exposure can be altered so as to form prism facets that arc arcs or other structures instead of merely localized discrete facets.
- arcs or other structures can direct light into the waveguide 18 even though the incoming path of the light varies with the path taken by the sun over the course of a day.
- the daily collection efficiency of the system 2 can be enhanced even when only using relaxed or no active solar tracking.
- the solar concentrators of such embodiments which can be referred to as reactive concentrators. operate by providing a large area region that can temporarily form for reveal) prism facets/injection structures using a material that reacts to bright light at or near the focus of a lens.
- the sun's heat and/or illumination is used to form the locations of the prism facets. This can be in the form of thermal expansion or other mechanical motion to bring the prisms in close contact with the guiding layer,
- the prism facets are positioned just along the outer surface of the slab waveguide, just outside of that surface ⁇ that is, outside of the waveguide).
- An intermediate medium that responds to the location/intensity of the sun causes a localized physical change in the refractive index at the point of focus allowing light that is reflected off the prisms to be coupled into the high-index guiding slab waveguide.
- a localized high refractive index surrounded by a low-index cladding is desirable (or necessary) for the purpose of allowing the prism to encounter incoming light once and not adversely strip already guided light.
- J00S3 Depending upon the embodiment, several potential phenomena are available to generate the necessary localized index change,
- a colloidal suspension of high index nanoparticles in a lower index fluid similar in optical properties to the outer cladding is provided.
- the particles can be smaller in size than the wavelength of light, and therefore seen as average and not individual scattering particles.
- An accumulation of high index particles causes the perceived index of refraction to rise creating the coupling window between the reflective prism facets and the guiding slab while still maintaining the lower-index cladding surround.
- FIG 6 a side elevation view of one exemplary embodiment of a solar energy system 122 employing a reactive concentrator section 124 in addition to PV cells 126 is shown.
- the reactive concentrator section 124 in particular is fo ⁇ ned from several layers stacked together
- On the top is an array 128 of lenses 130 used to lorm ( oca! points from the incident suniight
- a low index cladding layer 136 exists just below the lenses 130 followed by a high index guiding layer fe g., a slab waveguide layer or core) 138
- a mirror (reflective) rmcrostr ucture 140 sits below the high index guiding layer 138 with a gap 142 filled by a colloid m suspension (colloidal suspension) 144
- T he colloid 144 contains a low index fluid or gel with high index particles evenly dispersed within, achieving an average index similar to the cladding layer 136 found above the guiding layer 138
- the PV cells 12t> are placed at edge surfaces of the high index guiding layer 138 as with the solai energy system 2 of FIGS. 1-2 (also, while not shown, reflective coatings are placed on the other edge surfaces
- the solar energy system 122 can be understood as operating generally according to a process 150.
- sunlight is incident upon the solar concentrator section 124 at a step 154.
- the lenses 130 focus the light so that it passes through all of the layers of the solar concentrator section 124 (e g , the layers 136 and 138) so as to be incident on the rnirroi microstrueture 140 as spots.
- step 1 56 with high illumination flux, significant optical trapping forces are exerted on the particles suspended in the colloid 1 44. Particles outside the illumination cone undergo Browman motion causing them to constantly migrate Over time, more particle?
- the coupling windows should remain small to reduce the probability of a ray which is already guided from seeing the microstruciurc beneath and scattering out of the core (this will ultimately limit the distance light can be guided and can be a main consideiation of design),
- the angled prism facets of the mirror or giating reflect light at angles necessary to achieve TIR, such that the light reflected by the prism facets couple directly into the layer 1 ⁇ 8 i/ather than refracting into and out of the various layers), and eventually then arc channeled toward the PV ceils 126, at which electrical power is then generated, as indicated by a step 158.
- the colloidal accumulation is optically induced and occurs locally, the system is able to react to the position of the sun That is, as indicated by a step l oO, over time the angle of incidence of the sunlight upon the lenses 130 changes.
- the colloid 144 further responds so as to result in modified prism facets at the step 156.
- continued movement of the sunlight results in repeated performance of the steps 156, 1 58 and 160 (on a continuous basis).
- the colloid 144 can involve the suspension of titanium dioxide (TiO ⁇ ) particles These are subwavelength particles with a very high index of refraction and have potential to be easily trapped and manipulated with sunlight I he particles will likely be coated with silica, etc., to avoid clumping due to Vander Waals forces.
- the colloid 144 includes both the titanium dioxide particles, which are nanoscale.
- the photosensitive material repeatedly senses and responds to changes in electric fields of portions of the light, by drawing in some of the high dielectric index particles (that is, due to the light exposure, some of the particles move from one location to another within the overall colloid) so as to achieve optical trapping.
- the colloidal solution is only one of many potential methods for creating a high index window to couple to the wavegmde-'eore. Other static and mechanical possibilities exist as well as active electrical addressing.
- Phenomena including ⁇ electrophoresis can also be utilized to manipulate the location of particles. It will b ⁇ further understood that the solar energy system 122 of FIG. 6 employing the reactive solar concentrator 124 can be manufactured using processes similar to (albeit not identical to) the processes described above with respect to FIGS. 3-4B.
- a solar energy system 162 includes not only one or more PV cells 6 and the solar concentration section 4 with the slab waveguide 18 and the lens array 8 with the lenses 10 (as well as the prism facets 26) of the solar energy system 2 discussed above, but also includes first, second and third additional lens arrays 166, i 67 and 168.
- each of the lens arrays 166-168 includes a plurality of individual lenses 169. More particularly, the. lenses of the first, second and third lens arrays 166, 167 and 168 are respectively arranged along first, second and third planes parallel to the plane along which the lens array 8 is arranged, with the third, second and first planes being positioned successively outwardly away from the lens array 8.
- each of the lenses 169 of each of the lens arrays 166-168 is identical
- the lenses of the different lens arrays 166-168 can be different from one another and, indeed, in at least some embodiments different lenses of a given one of the lens arrays 166, 167 and/or 168 can also differ from one another
- the lenses 169 of the different lens arrays i 66-168 can be considered micro-lens arrays since the lenses are typically small in diameter (and equal in diameter to the lenses 10 of the lens array 8)
- the lenses 169 of the lens arrays 166-168 are intended to be nioveable relative to one another and/or the lenses 10 of the lens array 8 such that incident light that is incident upon the solar energy system 162 (and particularly incident upon the lenses of the lens array 166) at a variety of angles can still be ultimately directed in a manner so that the light is normally incident upon the lenses 10 of the lens array 8, that is, parallel or substantially parallel to the normal axis
- the lens array ] 67 in particular is nioveable along an axis of movement represented by an arrow 170 that is parallel to the inner and outer surfaces 22, 24 of the slab waveguide 18 and thus perpendicular to the normal axis 159.
- incident light 1 7] that is tilted relative to the normal axis 159 thus can he redirected so as to be normal upon the l ⁇ n ⁇ array 8 in a manner that is parallel or substantially parallel to the normal axis 159.
- the incident light 171 is tilted, light is effectively received and coupled by the solar concentration section 4 as if it were normally received and thus the solar concentration section is able achieve effective coupling of the light to the PV cells 6.
- the embodiment shown in FIG, 8 employs a triplet of micro-lens arrays where the second Sens array 167 in particular serves as a field lens that increases the fill factor at the output of the lens arrays (that is, the light as it proceeds toward the lens array 8). Nevertheless, in other embodiments other lens arrangements can also be employed. For example, in one other embodiment, only two lens arrays are employed (albeit such an embodiment can suffer from somewhat limited steering range and increased number of surface reflections, with the limited steering range being partly the result of the arising of spurious rays). In other embodiments, more than two lens arrays are present.
- the solar energy system 1 72 can be understood to include the both the Ions array 8 as well as the additional waveguide portions 19 of the solar concentration section 4 of the solar energy system T ⁇ f HG. 1 (e g., the waveguide 18 with the p ⁇ srn facets 2c>, as well as possibly the cladding layer l'i).
- the lens array 8 is movcable relative to the additional waveguide portions 19 of the solar concentration section, such that the additional waveguide portions can be moved leiative to the lens array 8 back and forth along a direction indicated by an arrow 177. the direction represented by the arrow 177 being parallel to the outer and inner surfaces 22 and 24 of the waveguide 18.
- a space 178 between the lens array 8 and the additional waveguide portions 39 can exist to facilitate such movement (such space can be filled with air or other cladding).
- the additional waveguide portions I ⁇ By appropriately moving the additional waveguide portions I ⁇ (this movement can involve a sliding movement along a bottom surface of the lens array 8) the additional waveguide portions can be positioned relative to the lenses 10 such that incident light 174 that is incident upon the lenses in a tilled manner relative to the normal axis 159 still is focused upon appropriate ones (in this example, an appropriate one) of the prism facets 26, Thus, even thought the incident light 174 is tilted, the light ultimate experiences TIR within the waveguide 18 and is directed to the FV ceils 6. [0063] As discussed with respect to FIG.
- the appropriate positioning of the additional waveguide portions IM relative to the Jens array 8 will vary depending upon the particular angle of incidence of the incident light S 74 relative to the normal axis 159 and thus, as that angle of incidence changes (e g , again due to movement of the sun during the course of the day or for some other reason) the relative positioning of the additional waveguide portions relative to the lens array 8 will need to be appropriately modified so that the incident light continues to be directed towards one or more of the prism facets 26
- a controller such as a microprocessor (not shown) that receives signals from one or more light sensors (also not shown) that detect the angie(s) of incidence of the incident light 1 74 (or at least predominant or substantial compon ⁇ nt(s) of that light; and based upon such received signals in turn adjusts the relative positioning of the additional waveguide portions 19 vis-a-vis the lens array 8.
- the amount of shifting of the additional waveguide portions 19 relative to the lens array 8 will correspond to the degree of tilt in the incident light; increased tilt will typically require increased amount of shifting.
- the amount of shifting required to achieve a desired effect will vary depending upon the embodiment, the amount of shifting will often be- quite small (e.g.. on the order of 1 millimeter or less).
- a solar energy device 1 82 not only is there present the lens array 8 as well as the additional waveguide portions 19 (and possibly the space 178 separating the two), but also there is an additional diffuse light collector 184 (which for example cars be a large area PV cell panel or solar-thermal panel) that is positioned outside of the additional waveguide portions alongside the outer surface 24.
- an additional diffuse light collector 184 which for example cars be a large area PV cell panel or solar-thermal panel
- incident light 186 that is weli-collimated is directed towards the prism facets 26 (particularly assuming that the additional waveguide portions 19 are appropriately aligned relative to the lens array 8), while other diffused light 1 88 that is incident upon the lens array 8 is not directed towards the prism facets 26 but instead is allowed to pass through the slab waveguide 18 completely and so is received at the diffuse light collector 184.
- w ⁇ li-colliniated incident light is provided to the PV cells 6 while diffuse light is received at the diffuse light collector 184.
- the solar energy system 192 includes waveguide portions 194 that are .similar to the additional waveguide portions 19 discussed above, and that particularly include a slab waveguide 195 and prism facets 193 by which light is directed to PV cells 196 at opposite ends of the slab waveguide. Additionally, the solar energy system 1 ⁇ 2 further includes a lens array 198 having a plurality of lenses 199.
- the waveguide portions 194 (and PV ceils 1 % mounted in relation thereto) are laterally shiftable relative to the lens array 198,
- the solar energy system 192 is configured to receive incident light that first impinges the system at an outer surface 191 of the waveguide portions 194 along which the prism facets 193 are located rather than at the lenses 199 of the lens array 198.
- incident light 200 passes through the outer surface 191 , proceeds through the slab waveguide 195 and through an inner surface 201 of ⁇ he slab waveguide (again at which can be provided a cladding layer), then through an air gap (or other possible cladding; 203 between the waveguide portions 194 and the lens array 198, and then through the lens array to the lenses l l >9.
- the light is then rcilected by the lenses back generally in the opposite direction toward appropriate ones of (m this case, one of) the prism facets 193, at which point the light experiences OR and is directed to the PV cells 190.
- the outer surface 191 of the slab waveguide 1 C; S is substantially transparent, while the lenses 199 are mirrors (or arc lenses with a mirror coating applied thereto).
- the lenses 199 in the present embodiment can be more appropriately termed micro- mirrors given their small size.
- FIG. 1 1 shows the light 200 incident upon the waveguide portions 194 to be normal to waveguide portions (that is, perpendicular to the outer and inner surfaces 191. 201 ), the solar energy system 192 again allows for incident light that is tilted to aiso be captured and directed towards the PV cells 1%.
- tilted incident light 189 also can be successfully directed to the PV ceils W6 by laterally shifting the waveguide portions 194 relative to the lens array 198 by an appropriate amount along a direction (back and forth along the direction) represented by an arrow 187.
- the use of the solar energy system 192 is particularly advantageous insofar as, due to the flatness (and typically robustness) of the outer surface 191 , the solar energy system realizes improved durability of packaging and case of cleaning.
- FICKS. 1 3 and 14 a further solar energy system 202 is shown in accordance with another exemplary embodiment of The present invention in which .slight movements of system components allow for tilted incident light to be captured at the PV cells of the device.
- the solar energy system 202 for reasons thai will be understood in view of the discussion below, can be particularly termed a micro-caiadioptric concentrator system.
- the solar energy system 202 among other things includes waveguide portions 204 including a slab waveguide 205 having first and second surfaces 206 and 208 that are opposed to one another on opposite sides of the waveguide, and further having prism facets 210 that are positioned along the surface 206. PV cells (one of which is shown) 212 are positioned at one (as shown) or more edge surfaces of the waveguide 205. Additionally, the system 202 also includes a lenslet array 214 that is positioned along ( v and spaced apart from) the first surface 206 of the waveguide 205 and a micro-mirror array 216 that is positioned along (and spaced apart from] the second surface 208 of the waveguide. In the present embodiment, air gaps (or other cladding) 218 are provided between the lenslet array 214 and the first surface 206 as well as between the micro-mirror array 216 and the second surface 208.
- the waveguide portions 204 and associated components can be laterally shifted relative to the lens components of the device, namely, laterally shifted relative to both the lenslet array 214 and the micro-mirror array 216 back and forth along a direction represented by an arrow 220.
- the waveguide portions 204 and associated components can be laterally shifted relative to the lens components of the device, namely, laterally shifted relative to both the lenslet array 214 and the micro-mirror array 216 back and forth along a direction represented by an arrow 220.
- incident Sight 222 that is parallel to an axis 230 normal to the slab waveguide 205 (that is, perpendicular to the surfaces 206, 208) initially impinges the solar energy system 202 at the outer surface of the lenslet array 214, after which it passes through the lenslet array (which causes some focusing of the light), through the air gap 218 between that lenslet array and the waveguide portions 204, through the waveguide portions including the slab waveguide 205. through the additional air gap 218 between the waveguide portions and the micro-mirror array 216 and up to an outer surface 224 of the micro-mirror array.
- the solar energy system 192 at this point the light is reflected by the micro-mirror array 2 I t? back inward towards the slab waveguide 205 and eventually passes through the slab waveguide and to appropriate ones of (in this example, one of) the prism facets 210, as a result of which the light experiences TlR and proceeds to the PV cells 212.
- incident light 226 that is tilled relative to the axis 230 is largely also directed eventually to the PV cells 212.
- incident light 226 that is tilled relative to the axis 230 is largely also directed eventually to the PV cells 212.
- a small amount of light is vignetted light 231 and escapes the system 202.
- the solar energy system 202 can achieve successful coupling of incident light to the PV cells 212 for incident light that is tilted at a variety of angles, it being understood that as the degree of tilting increases the degree of shifting will also need to increase. It will he understood that, in any given embodiment, it is possible for one or more actuators to be controlled Io move waveguide portions relative to lens array structures (including multiple structures such as both the lenslet array 214 and the micro-mirror array 216), with those lens array structures being stationary, or vice-versa, or to move all of the different components in various directions.
- lens array structures including multiple structures such as both the lenslet array 214 and the micro-mirror array 216
- PV cells are positioned along edges of slab waveguides so as to receive light directed by the slab waveguides to and outward form those edges.
- the confining of light, at known angles within waveguides as is achieved in such solar energy systems does not mandate that PV cells be oriented in such manners to receive thai light.
- additional arrangements are possible that allow for repositioning of PV cells or light extraction in a manner that achieves additional concentration. More particularly, referring now to FIGS.
- solar energy systems such as those discussed above can be modified in additional manners that facilitate the communication of light within the slab waveguides to PV cells that are intended to receive that light that are positioned in a variety of manners, and/or facilitate light extraction in a manner by which greater concentration is achieved.
- a modified version of the solar concentration section 4 of the solar energy system 2 of FIG. 2, referred to as a solar concentration section 234, is shown.
- the solar concentration section 234 in particular has, as shown, not only a lens array 2.32 with a plurality of lenses 236 as well as a slab (uniform-thickness) waveguide 238 having an outer surface 240, an inner surface 242 and a plurality of prism facets 246, but also additionally a fold prism 248 positioned at an edge 250.
- the fold prism 248 serves to rotate the light emanating from the waveguide 238 from lateral to downward propagation (e.g., a 90 degree rotation), which allows a ' PV cell (not shown) to be placed underneath the waveguide so as to be parallel to the outer surface 240 of the waveguide 238 rather than along the edge 250 of the waveguide.
- the solar energy system includes two solar concentration sections 254.
- each of the solar concentration sections 254 again includes a respective lens array 252 with a respective plurality of lenses 256 as well as a respective slab (uniform-thickness) waveguide 258 having a respective inner surface 262 and a respective outer surface 260, along which are formed a respective plurality of prism facets (not shown).
- Each solar concentration section 234 can have a thickness (that is, as measured between the outer surface of the lens array 252 and the outer surface 260) of, for example, 2 millimeters.
- a curved mirror reflector 268 positioned between the soiar concentration sections 254 is a curved mirror reflector 268 oriented so as to be concave toward the plane of the inner surfaces 262.
- the curved mirror reflector 268 can be any of a variety of different curved shapes depending upon the embodiment and, for example, can be an aspheric mirror reflector or a curved mirror reflector.
- the curved mirror reflector 268 extends outward away from the waveguides 258 farther than do the lens arrays 252, although this need not be the case in all embodiments.
- the curved mirror reflector 268 receives light provided to it from the waveguides 258 as that light proceeds out of the ends of the waveguides, and in turn focuses the light toward a central location 266 between the solar concentration sections 254 generally along the plane determined the outer surfaces 260.
- a packaged PV cell 270 can be positioned at this central location as shown so as to receive the focused, concentrated light.
- both the fold prisms 248 and the curved mirror reflector 268 of FIGS. 16 and 17, respectively serve to rotate the light emanating from the waveguides 238, 258, from lateral to downward propagation, albeit the curved mirror reflector provides the added benefit of further concentrating the light for receipt by the PV cell 270.
- concentration not only allows potentially the use of a smaller PV cell (which is desirable, due to the cost of larger PV cells), but also allows the PV cell to be more effectively operated (typically, PV ceils achieve greater efficiency of operation upon receiving more intense light),
- a planar concentrator array 272 is shown in cutaway to include six solar concentration sections 254 of the type shown in FIG. 17 (the waveguides 258 being shown in particular) and four of the curved mirror reflectors 268, with each of the reflectors being positioned between two corresponding ones of the solar concentration sections (where to of those sections are between two of the reflectors).
- the curved mirror re (lectors 268 direct light received from the solar concentration sections to PV cells (not shown) positioned beneath four different curved mirror reflectors 268. Notwithstanding the particular structure shown, it will be understood that any arbitrary number of solar concentration sections and curved mirror reflectors of this type can b ⁇ assembled into a larger structure in this manner Such a structure is not only easy and convenient Io fabricate but also in some cases can be easily stored fe g., the planar array can potentially be rolled up).
- An additional factor influencing the performance of a PV cell is the degree to which the PV cell is suited to receiving the particular Sight spectra that are provided to it. 1 urning next to FIGS 19-23, in at least some embodiments o ⁇ the present invention, solar energy systems arc configured to differentiate b ⁇ tw ⁇ n/among different light spectra and to direct different light components to different PV cells that are particularly well-suited (or receiving those respective light components, in at least some such embodiments, dielectric mirrors are incorporated into the solar concentrator design to split broad spectrum illumination mto multiple bands for collection using specialized PV cells.
- a solar concentration section 274 is employed.
- the solar concentration section 274, as shown, is similar to the solar concentration section 4 of FlG, 2 insofar as it employs a lens array 276 having multiple lenses 278 placed adjacent to a slab waveguide 280,
- the slab waveguide 280 can, as was the case with the slab waveguide 18 of MG. 2, include inner and outer surfaces 282 and 28 «, respectively, with the inner surface 2S2 being adjacent to the lens array 276 (it being fuither understood that a low index cladding layer such as the layer 16 of FlG. 1 serves as this inner surface 2S2), and prism facets 286 (two of which are shown) being formed along the outer surface 284.
- PV cells can be provided along outer edges 288 and 289 of the slab waveguide 280.
- the solar concentration section 274 additionally includes first and second dichroic mirrors 290 and 291 that are respectively positioned along the first and second edges 288 and 28 C >, respectively (and which would therefore be positioned between those edges and any PV cells intended to receive light emanating through those edges)
- the dichroic mirrors 2W, 291 are particularly configured to pass certain wav lengths of light and to reflect other wavelengths of light.
- first incident light 292 of wavelength ⁇ i (shown in dashed lines), upon impinging the lenses 278 and passing into the slab waveguide 280 and being reflected by a respective one of the prism facets 286, experiences TlR within the slab waveguide 280 and can proceed in cither direction towards the first edge 288 or the second edge 289.
- any such light that arrives at the second edge 28 l > is consequently reflected by the dichroic mirror 291 and thus proceeds in the opposite direction toward the first edge 288.
- the first dichroic mirror 290 is configured to allow light of wavelength ⁇
- the efficiency of operation of the PV cell can be maximized.
- second light 293 of wavelength ⁇ > that is incident upon the lenses 278 (shown in solid lines)
- that light also can proceed in through the lenses and into the slab waveguide where it experiences TlR due to interaction with the prism facets 286,
- the first dichroic mirror 290 is configured to reflect light of the wavelength of the second light (k ⁇ ) while the second dichroic mirror 2 C M is configured to pass such light.
- all of the second light of the wavelength ⁇ i only passes out of the waveguide through the edge 289 through the dichroic mirror 291 and, upon making such passage, can be received by a PV ceil that desirably is suited for receiving light of that frequency.
- an additional embodiment of a solar concentrations section .7.94 includes not only a lens array 296 with lenses 298 but also a first waveguide 300 and a second waveguide 301.
- the first waveguide 300 has a first surface 302 and a second surface 304. where the first surface 302 is in contact with the lens array 296 and the second surface 304 is in contact with the second waveguide 301 .
- first waveguide 301 includes a first surface 305 that is an outermost surface of the solar concentration section 294 and additionally a second surface 306 that is in contact with the second surface 304.
- the first surface 302 of the first waveguide 300 can b ⁇ formed by a low index cladding layer such as the cladding layer 16 of FlG, I , I lowever, in contrast to the embodiment of MGS. 1 -2, prism facets 308 ftwo of which are shown) are formed not along the second surface 304 of the waveguide 300 but rather along the first surface 302 that is in contact with the lens array 296.
- the second surface 304 instead of placing prism facets at the second surface 304, that surface instead is where a diehroic mirror (as well as possibly another cladding layer) is formed and, for purposes of the description below, the second surface 304 is considered to be such a dichroie mirror (albeit the second surface 306 of the second waveguide 301 or both of the surfaces 304, 306, can also be considered to be or include such a mirror).
- the second waveguide 301 it also has prism facets 310, two of which are shown, formed along the first ⁇ " outer) surface 305. Additionally as shown, at each of the longitudinal edges of the first and second waveguides 300, 301, further dichroie mirrors are placed in the same manner as was described with respect to F ⁇ G.
- a first dichroie mirror 31 1 is positioned while at a left edge of that same waveguide a second dichroie mirror 312 is positioned.
- a third dichroic mirror 313 is positioned while at a left edge of ihat waveguide a fourth dichroic mirror 314 is positioned.
- the solar concentration section 294 is capable of differentiating among four different types of light and directing those respective types of light to four different PV cells respectively. More particularly, first light 315 of wavelength ⁇ j that is incident upon the lenses 298, upon passing through the lens array 296 and passing into the first waveguide 300, is reflected by the dichroic mirror 304 and consequently reflected back up to appropriate ones of (in this example, one of) the prism facets 308 associated with that first waveguide.
- second light 316 of wavelength ⁇ 2 upon passing into and through the lens array 296 and into the first waveguide 300 similarly is reflected by the dichroic mirror 304 and received at the prism facets 308, Upon reaching the prism facets 308, each of the first and second light 31 5, 316, experiences TIR and is reflected within the first waveguide 300. Due to the additional operation of the first and second dichroic mirrors 311, 312 (in substantially the same manner as was discussed with respect to FICJ.
- the first light of wavelength ⁇ j is reflected by the second dichroic mirror 312 so that it cannot pass out of the waveguide 300 at its left edge, but instead all of the first light passes through the first diehroie mirror 31 1 and thus exits the waveguide through its right edge.
- the second light 316 of wavelength ⁇ is precluded from exiting the first waveguide 300 at its right edge associated with the first dichroic mirror 31 1 , at which such light is reflected, but is instead able to exit the first waveguide at its left edge at which is located the second dichroic mirror 312, which passes that light.
- both third light 317 of wavelength ⁇ s and fourth light 318 of wavelength X 4 upon entering the lens array 296 and passing through the first waveguide 300, are able to pass through that diehroie mirror and into the second waveguide 301 .
- the focused light 317, 31 8 reaches the prism facets 310, at which that light experiences TIR. Due to the presence of the diehroie mirror 304 (and possibly due to any further effect of any other layer such as a low index cladding layer at the second surface 306, etc), the third and fourth light cannot re-enter the first waveguide 300.
- the third light 317 is reflected at the left edge of the waveguide 301 and only passes out of that waveguide at its right edge by way of the third dichroic mirror 313, while the fourth light 318 is reflected at the right edge of the waveguide 301 and only passes out of that waveguide at the left edge by way of the fourth dichroic mirror 314,
- incident light can be separated successfully into four different light components ⁇ j, ⁇ 2 . ⁇ -j and ⁇ 4 , which respectively exit the solar concentration section at four different locations.
- the solar concentration section 324 of FlG. 21 like the solar concentration section 294 of FIG. 20 includes a first waveguide 320, which can be, for example, an infrared waveguide, and a second waveguide 32 L which can for example be a visible waveguide (again, each of the waveguides can include appropriate cladding along its outer surfaces so as to form the waveguides; also, there can be in some cases a planar first surface anti -reflective coating applied to various surfaces of the solar concentration section 324;.
- a first waveguide 320 which can be, for example, an infrared waveguide
- a second waveguide 32 L which can for example be a visible waveguide
- each of the waveguides can include appropriate cladding along its outer surfaces so as to form the waveguides; also, there can be in some cases a planar first surface anti -reflective coating applied to various surfaces of the solar concentration section 324;.
- the solar concentration section 324 instead employs a lens array 322 that is positioned in between the first and second waveguides 320, 321 , More particularly as shown, the lens array 322 includes a first lens subarray 326 that includes a plurality of lenses 328 that are directed concave up toward the first waveguide 320 and a second lens subarray 327 having a plurality of lenses 329 that are directed concave down towards the second waveguide 321, As shown, the second lens subarray 327 is thus closer to die second waveguide 321 than the first waveguide 320, and the first lens subarray 326 is thus closer to the first waveguide 320 than ih ⁇ second waveguide 321 , where a space 330 exists between the first and second lens subarrays
- the lenses 329 oi the second lens subarray 327 are not coated with any diehroie coating but merely serve as refractive lenses for any Sight (and particularly visible light) that reaches those lenses after passing through the reflective lenses of the first lens subarray 326, Given this a ⁇ angement, upon incident light 332 impinging the solar concentration section 324 via.
- a solar concentration section 344 is substantially identical to the solar concentration section 294 of FlG. 20 insofar as it includes a lens array 346, a first waveguide 350 and a second waveguide 35] , along with a dichroic mirror 348 positioned in between the two waveguides.
- dichroic mirrors can also he positioned along the edges oi the waveguides 350, 351 to further det ⁇ imine whether particular light components within the respective waveguides ⁇ it the waveguides at any particular longitudinal edges, although this need not be the case in all embodiments.
- each of the waveguides 350, 351 of the solar concentration section 344 is shown to include a respective longitudinal edge 352, 353, respectively, at which is positioned a respective folding prism 354, 355, respectively, as discussed above in relation to FIG 15 sjn alternate embodiments, reflectors can be employed in place of the folding prisms).
- a respective folding prism 354, 355, respectively can be employed in place of the folding prisms.
- the solar concentration section 344 achieves some oi the same benefits of each of the solar concentration sections of HG. 20 and FIG. 15, both in terms of concentrating light and directing certain light components to suitable PV cells, as well as arranging FV cells so as to be positioned in. a desirable manner (and a manner in which the different PV cells are positioned apart from one another) 1 his embodiment can further allow for the development of thin/small volume solar energy systems, and systems with improved polarization performance.
- an additional solai concentration section 364 includes both the solar concentration section 4 of FIGS 1-2 as well as additional components that allow for the separation of different light components and direction of those respective light components to different PV cells. More particularly as shown, in the embodiment of FH). 23, a reflective output coupler 362 is positioned at an edge 28 of the waveguide 18 as shown and in turn directs the received light 360 to a dichroic reflector 3(>6 that is located outside of the solar concentration section 4.
- the geometric concentration is therefore the waveguide length divided by the waveguide slab thickness (or twice the thickness where there exists symmetric coupling).
- concentration value assumes no focusing in the orthogonal direction, that is, the direction perpendicular to the thickness of the waveguide (e.g., as measured along the normal axis 159 discussed above! and also perpendicular to the length of the waveguide along which captured light generally proceeds toward one or more PV cells. Nevertheless, focusing in the orthogonal direction can also be achieved in various manners and can result in additional light concentration.
- the PV ceils need not occupy the entire widths of the edges of the waveguides along which those PV cells are positioned. That is, the exit apertures (the portions of the edges of the waveguides along which PV cells are positioned) need not be coextensive with the edges of the waveguides.
- the slab waveguide 18 of FIG. 1 having the first and second edges 28 and 30 need not be employed in conjunction with PV cells that extend the full width of the waveguide as do the PV cells 6 of FIG. 1. Rather, as shown in I- 3G. 24A.
- FV ceils 372 can instead be employed that only extend approximately one-third of the width of the waveguide 18. Assuming that mirrors 374 are positioned along the remaining portions of the edges 28, 30 that are not covered by the PV cells 372, light within the waveguide 18 that is not incident upon the PV cells continues to reflect back and forth within the waveguide 18 as represented by arrows 376 until such time as the light enters into one of the PV cells 372. ( ⁇ similar arrangement can be employed to achieve separation of different light components from one another). By reducing the si/e of the PV cells (and exit apertures) relative to the longitudinal waveguide edges in this manner, the geometric concentration ratio is increased.
- FIG. 24 B also includes a waveguide 378 that has first and second edges 379 and 380. respectively, and PV cells 38.? and mirrors 1$4 along each ol the respective edges, where the PV cells occupy about one-third of the widths of each of those respective edges and the mirrors along those edges occupy the remainders ol the widths of those respective edges.
- the edges 379, 380 of the waveguide 378 are not parallel to one another but rather are tapei ⁇ d such that the overall waveguide has a irap ⁇ /oidaS shape as viewed normal to the waveguide (that is as viewed along the axis 159 discussed above)
- reflection of the light (again as represented by arrows 38b) can be achieved that more rapidly results in arrival in the light at the PV cells 382 than in the case of FlG, 2*3 ⁇ .
- a trapezoidal arrangement is shown in HCi. 24B 3 it will be understood that other shapes are also possible including, for example, parallelogram arrangements or arrangements in which the edges of the waveguide are curved.
- the edge configurations arc selected so as to alter the reflection angles of the light being reflected off of the mirrors along the edges of the waveguide so as to increase the likelihood of reflections toward the PV ceils and thus the likelihood of capture of that light by the PV cells.
- HG. 24C shows yet another waveguide 3S8,
- a PV cell 392 JS only located along a first edge 390 of the waveguide while an opposite edge 391 of the waveguide is a mirror such that no light exits the waveguide at that edge, fhus, in such an embodiment, light is reflected not only by mirrored surfaces 394 existing along the first edge 390 ai which is located the PV cell 392 (which as m the cases of HOS. 24 ⁇ -24B does not occupy the entire width of the edge) but also is reflected at the mirrored edge 391 , as indicated by arrows 396.
- FIG. 24D still an additional waveguide 3 t; 8 is shown that also has the PV cell 392 and mirrored portions 394 along a first edge 397 but, instead of having a mirrored edge 391 as m FIG 24C instead has an edge 399 that is a Fresnel reflector or rotroreflcctor un the present embodiment, the Fresnel reflector is ⁇ x planar Fresnel reflector).
- the Fresnel reflector is ⁇ x planar Fresnel reflector.
- the use of other types of mirrors/p ⁇ sms at one edge of the waveguide can also be provided in seme embodiments, for example, where it is desired to achieve effectively the effect of a curved mirror on a planar surface.
- J0095] fuming to MCiS. 25-28R, control or influence over the direction of Sight proceeding within a waveguide such as the waveguides discussed above can be achieved not only through the use of mirrors and lenses but also by appropriate selection/configuration of the prism facets as well.
- every given prism facet can be configured to tend to direct/reflect light in a particular direction.
- each of the prism facets 402 is configured to direct/reflect light predominately in a direction indicated by a respective arrow emanating from that p ⁇ sm iacet. Further, as can be seen from F ⁇ . 25. given appropriate selection of such directional orientations of the prism facets 402, light from all of the prism facets can be directed generally towards a PV cell 404 located at a given edge 406 of the waveguide 400.
- HGS. 2t> ⁇ -2 ⁇ C show how appropriate selection of the prism facets can be used to achieve direction ol light towards any arbitrarily -located FV cell positioned along an edge of a waveguide. More particularly, each of F)GS.
- 26A-26C show respective exemplary waveguides 410, 420, and 430, respectively, at which first, second and third FV cells 415, 425 and 435, respectively, are located at first, second and thud positions along l ⁇ spective edges of the respective waveguide
- prism facets arc not shown with particularity in HGS 2 ⁇ -2e>( ⁇ it will be noted that tangent curves 417, 427 and 437 are shown instead So long as ihe prism facets are configured to dneci light m directions perpendicular to the icsnec ⁇ ' vc tangent curves 417, 427, and 437, in respective FIGS 2oB and 26C (and within the longitudinal plane of the waveguides), light will be general!) directed towards the respective PV cells 415, 425, 435 along directions generally indicated by respective arrows 419.
- PV cells 435 are positioned along both opposite edges of the waveguide 430, and it will be noted that there exists symmetry in the tangent curves 437 shown with respect to opposite halves of the waveguide.
- the waveguides need not have sides/edges that arc all flat, but instead can include one or more sides that arc curved.
- light direction can be controlled to such an extent that light can be effectively coupled to PV cells even though the PV cells merely occupy minor regions along one or more of the non-edge surfaces (e.g , the surfaces 22, 24 of the waveguide 18 of FIG. Ij of the waveguide.
- a errc ⁇ laiiy-shaped waveguide 440 having an outer cylindrical edge 442 that is mirrored/reflective that effectively directs light to an off-edge PV cell 444 by appropriately configuring prism iaecis 446 along that waveguide so as to direct light in the directions shown by arrows emanating from those pnsrn facets, that is, in directions toward the location oi the PV cell Due to the orientation of the prism facets 446, light is strongly directed toward the PV cell at the center of the waveguide. Further due to the mirrored edge 442, light is also reflected inward away from the outer cylindrical circumference as indicated by an arrow 448.
- the particular location of the PV cells 44 m terms of whether it is located on any particular one of the two non-edged surfaces is not critical due to the number of reflections that the light within the waveguide 440 undergoes, in particular, there is no need for the PV cell to extend into the waveguide in order for the PV cell to satisfactorily receive light.
- a radial concentrator be realized having a single PV ceil located at the center of the disk, but also in some embodiments the disk can be replaced with hexagonal sections to achieve higher fill factors between concentrator elements.
- a plurality of hexagonal slab waveguide portions 450 in particular can be assembled to form an overall waveguide assembly 452, where each of the waveguide portions 450 has a single associated PV cell 454 at its center toward which all light within that waveguide portion tends to be directed due to the orientation oi the prism facets.
- Exemplary orientation of prism facets within a section of an exemplary hexagonal waveguide portion 450 is shown in FlG. 28 ⁇ (particularly in a section of one such waveguide portion), with the particular configured orientations of the prism facets 456 being indicated by arrows emanating from those prism facets. It can be further noted that, in the rotatiotially-symmetrie embodiments of FIGS. 27-28R. the design of the coupling light extractor (eg., in terms of prism facet orientation) remains the same when rotated about a central axis.
- directionality of light flow within waveguides can be achieved at least m part by appropriate configuration of the prism facets, light can be further directed/coupled to PV cells with fewer passes along the slab waveguide and therefore achieve even greater efficiency
- the use of prism facets to achieve directionality and greater concentration can be combined with the use of any one or more of the other above-described techniques (e.g., those involving lenses, mirrors, reflectors, light component separation, etc.) to achieve desired direction of light within a slab waveguide toward PV cells and desired concentration of thai Sight. That is, the above-described methods involving light control using prism facets are independent of. but also comhinable with, the other light- concentrating/extracting designs also described above.
- a solar energy system can employ one or more of the features shown above in relation to one of the above-described systems with other features shown above in relation to other(s) of the above-described systems.
- one or more of the features can be modified in many different manners. For example, in some alternate embodiments, it is possible to arrange prism facets (or other injection features) along a surface of a waveguide that is adjacent to a lens array rather than along the opposite side of the waveguide. As already noted, a variety of different types of injection features can be implemented depending upon the application and embodiment,
- the present invention involves new types of solar concentrators that allow for efficient and inexpensive conversion of sunlight to electric power
- the concentrators collect sunlight from a large upward facing surface having prism facets/injection features and channel the rays via total internal reflection (TIRj within an internal (slab waveguide) region, where they are directed towards the edges of the structure.
- TIRj total internal reflection
- One or more PV cells are placed at locations where light is allowed to leak for collection and energy conversion. As described above, this can be at one or more ends of the slab region, where the slab terminates and light can be efficiently extracted.
- PV cells can be placed periodically along the length of the slab waveguide by providing a structure/device that allows for guiding of the light out of the slab waveguide and info the PV cells. In some such embodiments, this involves creation of a sharply curved region of the slab waveguide proximate to the PV cell. One or more simple bends in the slab waveguide/core will break the 11 R conditions and can thus simply allow for the extraction of light at several points along a concentrator.
- Solar PV systems typically arc placed in the outside environment to work, and are in general subject to degradation due to prolonged exposure to weather.
- the optical concentrator is exposed to weather, while the PV cell is typically better protected. Recognizing that the PV cell is often the largest single cost element in the system, it is desirable to design a system so that a functional PV cell and associated electronics can be 'recycled' if the optical concentrator is damaged.
- the concentrator car be made as a continuous sheet which is cut to the desired length, then attached to a linear PV ceil.
- the nature of a slab waveguide permits the guided light to be efficiently stripped from the guided mode and directed into the PV cell in several ways, for example: (1 ) by cutting the end surface at an angle, (2) by removing the cladding or providing an index - matching layer between the waveguide and the PV ceil, or (J) by introducing a sharp physical curvature or bend into the waveguide, so that the light is incident at less than the critical angle for total internal reflection.
- These features can be pr ⁇ -form ⁇ d into the waveguide sheet, but they can also be incorporated into the mounting for the PV cell, so as to be readily implemented in relation to (for action upon) any region of a waveguide to which they are attached,
- ⁇ slab waveguide typically is a multiple optical mode structure which can guide light without loss as it propagates through the slab.
- a slab waveguide typically consists of a high index core surrounded by a lower index cladding on the top and/or bottom. Converting light from normal incidence on the face of the slab into light which is propagating within the slab requires some kind of structure for deflecting the light, which will not then act to eject (or allow excessive escaping of) light already trapped within the slab.
- One way to achieve proper guiding is to provide a localized coupling region with an index comparable to the core.
- this can involve using a colloidal suspension of high-index, sub-wavcl ⁇ ngth-siz ⁇ d, particles within a lower index liquid.
- Bright incident light causes optical trapping, increasing the density of the high index particles and so increasing the overall refractive index where the incoming light accumulates the particles yielding an increase in the average index of refraction.
- a localized increase in the refractive index allows light that scatters from the suspended particles, or reflects from a nearby optical structure (which is otherwise not interacting with the guided light within the slab), to be trapped within the slab region and guided to the PV cell [00106]
- At least some embodiments of the above-described solar energy systems/solar concentrators are suited for the roll-to-roll processing method of manufacture.
- a roll process produces the lenslets by embossing them onto a layer of low index plastic which covers the higher index slab region.
- the back surface can be made using a similar process, for the actively aligned version, or using a sandwich of materials, such as a perforated mesh separating a liquid-filled layer from a patterned rear surface, ⁇ n all cases, the multiple layers of the concentrator can be laid onto one continuous substrate creating a long, flexible product at a very low cost.
- the concentrator can be formed onto rigid panels using a more conventional, if more expensive, manufacturing process, [00107]
- the present invention involves an overall slab waveguide concentrator geometry using focusing lenses and localized injection feat tires, where either the localized injection features are permanent or alternatively the injection features are reactive (formed in response to incident light), where multiple specific materials and structures can he used for formation of the injection features.
- the slab waveguide format is extremely compact in comparison to many conventional active or passive concentrator optics. Since material costs are a significant part of the overall system cost, this entails a potential cost savings.
- the reactive nature of the concentrators eliminates the need for the active tracking usually associated with solar concentration. Indeed, such embodiments arc distinctive in that no absorption is required.
- the reacting material can potentially react lossl ⁇ ssly, as for example through a change in index. Even If the reacting material does require some absorption, the light which is guided within the slab does not (on average) encounter the reacting material again, and so would experience only a single loss point.
- the geometries of at least some of these embodiments arc attractive In that very high input to output area ratios can be achieved.
- At least some embodiments of the present invention are intended facilitate achieving the benefits associated with both concentrated PV systems as well as non-concentrated photovoltaic systems by both collecting direct sunlight into a concentrated high-efficiency photovoltaic cell, and also (possibly simultaneously) directing diffuse sunlight into a less efficient photovoltaic ceil [001 10]
- at least some embodiments ol the present invention involve extracting and concentrating the direct sunlight to the edge of the illuminated area for reception by one or more PV cell(s), while allowing diffuse light to pass through the waveguide for collection by one or more other PV cell(s).
- light which enters the leas array 8 normally is focused onto the replicated p ⁇ sm facets 26 and coupled into the slab waveguide 18.
- light which enters the lens array 8 at any other angle is focused by the l ⁇ nsi ⁇ ts onto a transparent region of the rear surface of the waveguide, missing the p ⁇ sm (accts 26. and is transmitted through the rear surface of the waveguide 24 substantially without attenuation.
- an area-efficient hybrid photovoltaic system can be made by placing a conventional solar panel directly beneath the micro-optic slab concentrator. On cloudless days, most of the energy would be generated by the efficient photovoltaic cell via the concentrator By comparison, on cloudy days, a smaller total amount of energy, bypassing the slab concentrator, would be generated mostly by the photovoltaic panel.
- Each of the above- described embodiments of solar energy ⁇ y stems-'solar concentrators are potentially manufacturable at extremely low cost, as compared with the cost of manufacturing conventional PV cell material from amorphous or crystalline Silicon. Due to the compliance with roll-to-roll processing, it is likely that this concentrator design will exist as flexible sheets several meters in length They could be tilted onto roofs or act as tents to provide local power generation for homes or temporary installations.
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- Ophthalmology & Optometry (AREA)
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Abstract
Applications Claiming Priority (2)
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US9827908P | 2008-09-19 | 2008-09-19 | |
PCT/US2009/057567 WO2010033859A2 (fr) | 2008-09-19 | 2009-09-18 | Systeme et procede de capture d'energie solaire et procede de fabrication associe |
Publications (2)
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EP2326889A2 true EP2326889A2 (fr) | 2011-06-01 |
EP2326889A4 EP2326889A4 (fr) | 2013-07-03 |
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EP09815304.2A Withdrawn EP2326889A4 (fr) | 2008-09-19 | 2009-09-18 | Systeme et procede de capture d'energie solaire et procede de fabrication associe |
Country Status (9)
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US (2) | US9274266B2 (fr) |
EP (1) | EP2326889A4 (fr) |
CN (1) | CN102216695B (fr) |
AU (1) | AU2009293000A1 (fr) |
BR (1) | BRPI0918865A2 (fr) |
IL (1) | IL211778A (fr) |
MX (1) | MX2011002993A (fr) |
WO (1) | WO2010033859A2 (fr) |
ZA (1) | ZA201102038B (fr) |
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Also Published As
Publication number | Publication date |
---|---|
BRPI0918865A2 (pt) | 2017-03-21 |
WO2010033859A2 (fr) | 2010-03-25 |
IL211778A (en) | 2015-01-29 |
EP2326889A4 (fr) | 2013-07-03 |
CN102216695B (zh) | 2013-12-25 |
IL211778A0 (en) | 2011-06-30 |
WO2010033859A3 (fr) | 2010-07-22 |
MX2011002993A (es) | 2011-05-30 |
US20110226332A1 (en) | 2011-09-22 |
ZA201102038B (en) | 2012-05-30 |
US20160178879A1 (en) | 2016-06-23 |
AU2009293000A1 (en) | 2010-03-25 |
CN102216695A (zh) | 2011-10-12 |
US9274266B2 (en) | 2016-03-01 |
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